Resin composition



United States Patent 3,437,715 RESIN COMPOSITION Ettore Da Fano, Pasadena, Calif., assignor, by mesne assignments, to Pittsburgh Plate Glass Company, Pittsburgh, Pa., a corporation No Drawing. Filed Apr. 15, 1955, Ser. No. 501,727 Int. Cl. C08f 1/80, 21/02, 21/00 US. Cl. 260-863 7 Claims ABSTRACT OF THE DISCLOSURE This invention relates to resin compositions and has particular reference to polymerizable polyester resin compositions.

One of the principal objects of this invention is to provide novel polymerizable compositions wherein the polymerizable component is a polyester resin.

Another object of this invention is to provide novel polymerizable polyester resin compositions which are stable during extended periods of storage yet which can be readily cured to provide castings which are sound and possess superior optical properties.

Another object of this invention is to provide novel stabilized polymerizable polyester resin compositions which are capable of rapid curing wherein the peak of exotherm is reached sooner than with conventional polyester resins, but mherein the exotherm is substantially lowered.

A further object or" this invention is to provide polymerizable polyester resin compositions which in the uncatalyzed condition are stable during extended periods of storage yet which, upon addition of a polymerization catalyst thereto, undergo polymerization at a faster rate than do conventional polyester resins.

Yet another object of this invention is to provide novel polymerizable polyester resin compositions which cure to provide castings having improved physical properties, including hardness, heat distortion point, flexural strength and notched-fiexural strength.

Other objects and advantages of this invention, it is believed, will be readily apparent from the following detailed description of preferred embodiments thereof.

Certain difiiculties are encountered in the manufacture of cast articles from polymerizable polyester resins, particularly in the casting of transparent sheets free of optical distortions, blemishes, etc. One of the most troublesome problems is brought about by the heat of reaction or exotherm which is encountered in casting the sheets, especially those /2-inch or greater in thickness. This problem increases not only with thickness of the sheet to be cast, but also with the other two dimensions of the sheet. The rate of gelation required is such that the resulting heat development becomes dangerously rapid, resulting in setting up stresses and strains in the sheet. Moreover, initial temperature differences in various points of the cast article are greatly magnified during the exothermic period, causing uneven shrinkage of the article. Thus, the dimensions of articles which can be cast from polyester resins are greatly limited. In all cases, the casting operation is very critical, requiring strict controls of mold temperature and very accurate timing of the heating operation.

ice

Another problem peculiar to the product of transparent polyester sheets resides in the fact that it is customary to include in commercially available polyester resin compositions a stabilizer or gelation inhibitor, added for the purpose of permitting storage of the resin without the danger of premature gelation or polymerization. However, such inhibitors tend to lengthen the gelation time during casting, often resulting in optical imperfections in the form of striations brought about by convection currents.

Variations in the rate of gelation due to variations in individual batches of polyester resin is another major problem. It is not always possible to correct the differences between two batches of the same type of resin by adjustment of the catalyst system, resulting in aggravation of the difficulties set forth above.

The present invention is designed to provide a polymerizable polyester resin composition which is not subject to the above and other disadvantages heretofore encountered. The invention is based upon the discovery that resin-soluble organic copper salts, when added in relatively small amounts to catalyzed polyester resin compositions, function as promoters to increase the rate of gelation, yet at the same time tend to lower the peak of exotherm. Additionally, such copper salts function as gelation inhibitors when added to uncatalyzed resins, and to supplement the effects obtained with conventional inhibitors.

The present invention is broadly applicable to polymerizable polyester resins. These resins are now conventional in the art and comprise liquid, or at least fusible, polyesters, or mixtures of such polyesters and an ethylenically unsaturated monomer. These resins polymerize to the hard, thermoset stage by heating in the presence of a peroxide catalyst. The polymerization is of the addition type, that is reaction takes place at the points of carbon to carbon unsaturation, sometimes even in the absence of polymerization catalysts and at room temperature. This is especially true in the case of polymerizable mixtures of polyesters and the ethylenically unsaturated monomers. For example, a polyester of maleic acid or fumaric acid and a glycol such as propylene glycol or di-ethylene glycol in the presence of a monomer such as styrene, unless inhibited, will begin to gel almost at once.

The linear polyester is ordinarily prepared by reaction of an unsaturated dibasic acid with a dihydric alcohol, and frequently, though not necessarily, a saturated dicarboxylic acid or a dicarboxylic acid which is free from ethylenic unsaturation. Typical unsaturated acids which may be utilized include the following:

TABLE A Ethyl maleic acid Pyrocinchoninic acid Xeronic acid Itaconic acid Carbic acid The acids (or anhydrides) which are alpha, beta- Maleic acid Fumaric acid Aconitic acid Mesaconic acid Citraconic acid ethylenic, alpha, beta-dicarboxylic, such as maleic acid or maleic anhydride, are particularly useful.

The dihydric alcohol component may be selected from the following group:

Ethylene glycol Diethylene glycol Triethylene glycol Polyethylene glycol 1,3-propylene glycol Halogen substituted glycols, for example mono-chloro derivatives, are also useful.

As indicated hereinabove, it is sometimes desirable to utilize a quantity of a saturated dicarboxylic acid or a dicarboxylic acid which is free from ethylenic unsaturation in preparing the polyester. The principal functioning groups in these non-ethylenic acids are carboxyls (-COOH) which react through esterification. Such acids in the polyester add to the molecular length though they do not cross link the polyester molecules at points intermediate therein by addition of the monomer. Often such non-ethylenic dicarboxylic acids improve the properties of the resin into which they are introduced. Examples of such acids which may be utilized include the following:

TABLE C Suberic acid Azelaic acid Phthalic acid Tetrachlorophthalic acid Succinic acid Sebacic acid Adipic acid Dimethyl succinic acid Halogenated derivatives of the above acids TABLE D Octadecatrienoic acid Clupanodonic acid Acetic or propionic acid Linolenic acid Linoleic acid Elaeostearic acid The preparation of the polyester component is carried out substantially as follows: The dihydric alcohols of Table B (which preferably contain no more than carbon atoms) are usually employed in approximate molar equivalency or slightly in excess of such equivalency of the sum of the acids of Tables A, C and D. Usually, this excess will not exceed 10 percent or percent and it may be lower. The excess glycol facilitates reduction of the acid number of the polyester.

The ethylenically unsaturated dicarboxylic acid may constitute the whole of the acid component of the polyester, but usually it is preferred to include at least some of one or more of the non-ethylenic acids from Table C. The amount of acid or acids from the latter table is capable of variation over a broad range. The minimum is, of course, none at all, and the maximum may be 10 or 12 mols per mol of the acid from Table A. Naturally, as the percentage of the acid from Table C is reduced, the polyester assumes more and more closely the character of the polyester containing only acid or acids from Table A. It is impossible to state an absolute minimum to the efiec tive amount of acid from Table C.

A component from Table D is also optional, dependent upon whether an air drying polyester is desired. A range of one mol of acid D to 2 to 12 mols of acids A, or A and C, is ordinarily preferred.

Appropriate ranges of the several components of the polyester may be tabulated as follows:

(A) Ethylenic dicarboxylic acid-2 to 12 mols.

(C) Non-ethylenically unsaturated dicarboxylic acidoptional, but if present% to 144 mols.

(D) Drying oil acidoptional, but if present-l mol per 2 to 12 mols A-l-C.

(B) Dihydric alcoholequivalent or in slight excess of A+C+D.

Conditions of reaction in preparing polyester In carrying out the esterification of the dihydric alcohol and the acid or acids, conventional principles are adhered to. Acid catalysts may be added. The reaction may be conducted under an atmosphere of carbon dioxide or nitrogen gas. Xylene or other nonreactive solvent may be included and the reaction may be conducted by heating the mixture to reaction temperature, e.g., to that at which water is expelled from the system. It is continued until water ceases to evolve and the acid value of a sample is reasonably low, e.g., 5 to It should not be continued so long as to result in infusibility of the polyester. Usually a temperature of C. to C. or 200 C. and a reaction time of 2 to 20 hours is sufficient to effect the esterification.

The ethylenically unsaturated monomeric compound which is mixed with the polyester to form the polymerizable composition is preferably liquid and usually contains the reactive group CH C linked to a polar group. Included are the following compounds:

Styrene Methyl styrene p-Methyl styrene Divinyl benzene Indene Unsaturated esters such as:

Vinyl acetate Methyl methacrylate Methyl acrylate Allyl acetate Diallyl phthalate Diallyl succinate Diallyl adipate Diallyl sebacate Diethylene glycol bis (allyl carbonate) Triallyl phosphate Esters such as those of monohydric or polyhydric alcohols, (methyl, ethyl, propyl, allyl, methallyl, vinyl) and an unsaturated polymerizable monocarboxylic acid (acrylic, methacrylic, chloroacrylic) Esters of monohydric unsaturated alcohols (allyl, vinyl, methallyl, crotyl) and mono or polycarboxylic acids (acetic, propionic, succinic, etc.)

Esters of alpha, beta unsaturated dicarboxylic acids maleic, fumuric, itaconic) and monohydric alcohols (methyl, ethyl, propyl, isopropyl, amyl) Any one of these vinylic monomers (including syrupy mixtures of monomer and polymer) may be combined with any of the polyesters prepared from components A and B, A, B and C, A, B and D or A, B, C and D as previously described.

Mixtures of any two or more of the foregoing vinylic compounds and the polyesters can be used.

The vinylic monomer usually will comprise from 10 percent to 60 percent upon a weight basis of the copolymerizable mixture and the mixtures containing 20 percent to 40 percent or 50 percent by weight of monomer are preferred.

Because of the strong tendency of mixtures of polyesters and ethylenically unsaturated monomers to gel prematurely, it is ordinarily necessary to add to the mixture a gelation inhibitor. Many materials have been utilized for this purpose, for example, phenolic compounds such as quinone, hydroquinone, catechols, and the like. However, it has been found that the beneficial effect of the organic copper salts upon a polymerizable polyester resin N-X 1 R3 R4 wherein R R R and R are organic radicals and X is an acid radical.

The following are some of the quaternary ammonium salts which function as stabilizers or gelation inhibitors for polymerizable polyesters or mixtures of such polyesters and ethylenically unsaturated monomers:

One important group of quaternary salts comprises those with a benzyl group and three alkyl groups (methyl, ethyl, propyl, butyl, amyl, or the like) directly attached to ammonium nitrogen. These compounds may be represented by the formula:

alkyl alkyl benzyl-N alkyl X X being an acid radical of an acid at least as strong as acetic acid (dissociation constant l.75 l

Another important class comprises quaternary ammonium salts where one hydrocarbon group is higher alkyl and contains at least 8 and up to 18 carbon atoms, and three hydrocarbon groups are lower alkyl containing up to 6 carbon atoms (methyl, ethyl, propyl, butyl, hexyl). The structure of such compound may be represented by the formula:

lower alkyl lower alkyl higher alkyl-N lower alkyl X X again being an acid or negative group of an acid at least as strong as acetic acid.

Salts of quaternary ammonium hydroxide can be dissolved in polyesters of alpha, beta-ethylenic alpha, betadicarboxylic acids and dihydric alcohols (or their derivatives as modified by dicarboxylic acids and/or drying oil acids) to provide products that can be stored for very long periods without risk of gelation. The stabilizers are preferably added to the polyester while the latter is hot.

The quaternary ammonium type inhibitors are covered by Parker Patent No. 2,593,787.

A second class of inhibitors useful in combination with metal compounds such as copper naphthenate in polymerizable resin compositions is the teritary amine salts. The following are some of the inhibitors within this class of compounds:

Trimethylamine hydrochloride Trimethylamine hydrobromide Trimethylamine hydroiodide Dimethylaniline hydrochloride Dimethylaniline hydrobromide Triethylamine hydrochloride Tri-n-butylamine hydrochloride Tribenzylamine hydrochloride Tribenzylamine hydrobromide N benzylaniline hydrochloride Benzyl methylamine hydrochloride These materials are incorporated into the polymerizable polyester resin composition in the same manner as the quaternary ammonium compounds.

To formulate stabilized or non-gelling mixtures of (1) an unsaturated polyester of a dihydric alcohol and an acid comprising an alpha, beta-dicarboxylic alpha, beta-ethylenically unsaturated acid and (2) an ethylenically unsaturated monomer, it is preferred to dissolve the quaternary ammonium salt or the tertiary amine salt as an inhibitor in the polyester component. This is best accomplished by adding the salt to the polyester while the latter is hot, for example at about 150 C. or to such other temperature as will effect rapid and complete solution. This can be determined by observation, as it is easy to see when all of the inhibitor has disappeared into the polyester. The inhibitor is usually added in an amount of about 0.01 percent to 2.0 percent by weight of the mixture of components 1 and 2.

The monomeric material is normally added in an amount of about 10 percent to 60 percent by weight of the stabilized polyester mixture. Preferably it is added at a temperature of about 120 C. Since the unsaturated polyesters are usually quite viscous or even solid at room temperature, they should be sufiiciently warm to mix with a dissolve in the monomeric compound. The quaternary ammonium compounds and the tertiary amine salts stabilize the copolymerizable mixtures while the ethylenically unsaturated monomer is being incorporated therein. When the mixture is cooled to room temperature, it will remain stable for a considerable period of time.

To cure the polymerizable mixture, a peroxide catalyst is added in an amount of about 0.1 percent to 5 percent by weight of the polymerizable components, and the mixture raised to curing temperature. Typical peroxides which can be utilized include the following.

Low temperature types (30 C. to C.):

Acetyl benzoyl peroxide Peracetic acid Hydroxyheptyl peroxide Isopropyl percarbonate Methyl ethyl ketone peroxide Cyclohexanone peroxide Cyclohexyl hydroperoxide 2,4-dichlorobenzoyl peroxide Cumene hydroperoxide Intermediate temperature types C. or above):

p-Butyl hydroperoxide Methyl amyl ketone peroxide Acetyl peroxide Lauroyl peroxide Benzoyl peroxide Methyl cyclohexyl hydroperoxide t-Butyl permaleic acid t-Butyl perbenzoate Di-t-butyl diperphthalate High temperature types C. or above):

t-Butyl perphthalic acid p-Chlorobenzoyl peroxide t-Butyl peracetate High temperature types (100 C or above) :Continued Di-t-butyl peroxide Dibenzal peroxide Example l.An interpolymerizable mixture was prepared comprising (A) two parts by weight of a polyester comprising equal mols of maleic acid and phthalic acid esterified with propylene glycol slightly in excess of stoichiometric amount with respect to the dicarboxylic acids, (B) one part by weight of a C=CH monomer, namely styrene, and (C) a mixture of gelation inhibitors consisting of 0.1 percent by weight of trimethyl benzyl ammonium chloride and 0.001 percent by weight of quinone. Both percentages are based upon the combined weights of polyester and styrene.

A number of sets of samples of this polymerizable mixture were prepared, the samples in a given set being varied with respect to the other samples of the same set by incorporation therein of different polymerization catalysts.

The following catalysts were employed to initiate polymerization of the polyesters and monomers herein disclosed. For convenience, the materials are designated by key letters.

TABLE 1 A-Benzoyl peroxide BLauroyl peroxide C--Tertiary butyl hydroperoxide D-Methyl ethyl ketone peroxide as a 60 percent solution in dimethyl phthalate.

ECumene hydroperoxide F4 percent solution in carbitol of a 60 percent solution in water of thioacetic acid. This is preferably employed in combination with a peroxidic catalyst.

In each of the examples herein, the total amount of catalyst or mixture of catalysts was 1.0 percent by weight based upon the polyester and monomer.

The composition of the several sets were varied with respect to each other by variations of the content of copper naphthenate incorporated as a control of gel time and/ or tank life. The samples in the first set contained no copper naphthenate and the samples of this set constituted controls with which the corresponding samples of the other sets were compared in order to determine the effect of the copper content thereof as a promoter of gelation.

Tests to determine gel time and tank life were conducted upon these samples. The gel tests were conducted in a standard General Electric gel tester at a bath temperature of 150 F. In subsequent examples where gel times were determined this same procedure was followed.

The gel time constitutes a criterion of the rate of cure It will be observed that with each of the catalysts, at least at some concentrations, copper has a pronounced synergistic effect, greatly promoting gelation. However, with different catalysts, the amount of copper required to produce maximum promotion tended to vary. In most instances, good results were obtained by use of about 0.08 to 08 part of copper per million of resin, although in many cases between about 0.008 and about 8.0 parts of copper per million of resin were effective. More than this amount of copper could be used in some cases, but there is no particular advantage in thus increasing the copper content in conventional resin systems.

It has been observed that even though the rate of gelation is promoted by the copper present in the mixture, the exothermal rise during the polymerization reaction remains relatively low with respect to that taking place in the absence of copper. This is often quite desirable. The proportions of copper as given in the table refer to elemental copper.

The mixtures could be cured by heating to between about C. and about 150 C. for a period of about 3 to minutes, the specific temperatures and times being dependent upon the thickness of the article being formed, and other factors. The article may be further hardened by baking at about 150 C. for 30 to 120 minutes. Good, hard and optically clear resin articles of obvious utility for such uses as the formation of castings of various kinds, as clear sheets of plates, for use in airplane windows and other types of glazing, may thus be formed. The resins may also be mixed with various fillers and fibrous materials, such as fiber glass, in the formation of so-called laminates.

It is a remarkable fact that although the soluble copper compounds, such as copper naphthenate, when employed in extremely small amounts, constitute effective promoters of gelation in the polymerizable mixtures, in many instances, the same compounds, even at corresponding concentrations may substantially extend the so-called tank life of said mixture. The tank life may be regarded as the time the mixture can be stored at about 77 F. after the catalyst has been incorporated into the same before the mixture tends unduly to gel. Long tank life is often a desirable property, inasmuch as it is frequently desirable to make up batches which by reason of size, or other causes, must be stored for some time before use.

The effects of soluble copper upon the tank life of a number of the mixtures of this example is illustrated by the following table, wherein the copper is employed in the form of the naphthenate.

TANK LIFE AT 77 F.

of the catalyzed mixtures; the shorter the gel time the faster is the rate of cure.

The catalyst content, the copper content (in the form of the naphthenate) and the resultant gel times obtained from the several samples are tabulated as follows:

Example II.The polyester of this composition comprised 75 parts by weight of maleic anhydride and 25 percent upon alike basis of phthalic anhydride, esterified with propylene glycol in an amount slightly in excess of stoichiometric ratio with respect to the total of the acid. An

GEL TIMES FOR COPPER CONCENTRATIONS (TIME IN MINUTES) Catalyst 1 percent Sample 1, Sample 2, Sample 3, Sample 4, Sample 5, total based upon no copper 0.008 part 0.08 part 0.8 part 8.0 parts resin mixture (control) per million per million per million per million copper copper copper copper 4. 0 4. 1 3. 5 I. 2. 7 4. 1 4. 2 1. 9 1. 9 1. 2 3. 3 4. 3 2.8 2. 2 2. 3 B 3.0 3.0 1.9 7.2 8.8 C+0.1% of F.. 4. 0 2. 25 1. B5 2. 7 2. 0

interpolymerizable mixture was prepared comprising, polyester 2 parts by weight, styrene 1 part by weight, trimethyl benzyl ammonium chloride 0.1 percent based upon the total resin, and quinone 0.0001 percent upon a like basis.

The mixture was divided into two sets of samples, one set being maintained as a control. To the other set was added 0.8 part by weight per million of mixture of copper as the naphthenate. The samples were catalyzed with a number of different catalysts taken from Table I, and gel times were conducted upon the samples. The results obtained with and without copper naphthenate in the samples are tabulated as follows:

Catalyst 0.1 percent based Sample 6, no copupon resin mixture Sample 7, 150 gel per, 150 gel time time, 0.8 per mil- It will be observed that in each instance, there was a substantial reduction in gel time in the mixtures containing copper naphthenate. The latter is a good promoter of gelation when employed in the mixture in an amount of about 0.8 part per million.

Example III.The polyester in this example was of a mixture of 2 mols of maleic anhydride and 3 mols of phthalic anhydride. The glycol was propylene glycol utilized in an amount slightly in excess of the stoichiometric equivalency. An interpolymerizable mixture was prepared comprising 67 parts by weight of the foregoing polyester and 33 parts by weight of styrene. The gelation inhibitors in the mixture comprised 01 percent by weight based upon the resinifiable mixture of trimethyl benzyl ammonium chloride and 0.009 percent upon a like basis of quinone.

The mixture was divided into two sets of samples; duplicatory catalysts from Table 1 were added to the two sets and to one set was added 0.8 part by million of copper in the form of the naphthenate. Copper was omitted in the other set which constituted a control. Gel time and tank life determinations were conducted upon a number of the samples. The results are tabulated as follows:

Example IV.For this example a polyester was employed which was of about 2.2 mols propylene glycol and equal mols of maleic acid and phthalic acid, together with 0.1 percent by weight based upon the mixture of triphenyl phosphite; 73 pounds of this polyester was mixed with 27 pounds of styrene. The gelation inhibitors comprised 0.1 percent by weight based upon the mixture of trimethyl benzyl ammonium chloride and 0.0025 percent upon a like basis of quinone. Ultraviolet absorbers, namely, o-hydroxyacetophenone and methyl salicylate in the respective amounts of 0.1 percent by weight and 1 percent upon a like basis were added.

To samples of the mixture was added 1 percent by weight based upon the mixture of catalysts selected from Table I, and to one set was added 0.8 part per million of copper in the form of the naphthenate.

A matching set of samples, but without copper, Was retained and the .two sets were then subjected to gel time determinations as in the preceeding examples. The results are tabulated as follows:

Catalyst 1 percent by weight Sample 12 without Sample 13 with 0.8 upon mixture copper, 150 gel part per million of In each instance, it was found that the copper in the concentrations indicated, had a pronounced synergistic effect upon the gelation of the mixture. The mixtures could be cast and otherwise formed into articles which could be cured to hard resistant state at temperatures of about C. to 150 C., the time required for cure being from a few minutes to several hours, dependent upon the temperature and the massiveness of the article being formed.

It is also possible to combine a polyester such as one of those disclosed in the foregoing examples or a mixture of such polyesters, with other monomeric materials such as methyl methacrylate. One such polyester resin blend has the following composition:

Samplet) with 0.8 part Sample 11 Sample 8 per million Sample 10 with 0.8 part Catalyst 0.1 percent by weight without of copper (as with no copper million copper 150 naphtheper, 77 taut: of copper (as gel time nate) 150 life (hrs) naphthe- (min.) gel time nate), 77 tank (min.) life (hrs) A tug-15% 18-22 B 22.9 14.0 A+0.1% upon mixture of F 2%6% 1418 B+O.1% upon mixture of F %1 4%8% C+0.1% upon mixture of F 4.3 3. 4 1-4 11% It will be observed that in some instances, the addi- Mols tion of copper reduced the gel time and at the same time, A p cac d 6 the tank life was extended, often to a surprising de- Phthallc 301d 4.8 gree. This was especially true in connection with those M31610 aCld 5- samples containing F (thioacetic acid) as a promoter. Dlethylene glycol This is a surprising result, inasmuch as it might be ex- Propylene glycol pected that a material which would reduce gel time would also reduce the tank life.

styrene, 0.3 part trimethyl benzyl ammonium chloride, 0.004 part quinone, 0.2 part o-hydroxyacetophenone, and 0.16 part of triphenyl phosphite. The resulting polyester resin can be blended with methyl methacrylate and additional styrene to give a composition which is well adapted for casting purposes. It may be catalyzed with any of the peroxygen compounds of Table I, preferably in an amount of about 1.0 percent by weight based upon the blend. A soluble copper compound, such as copper naphthenate, then may be added in an amount such that there is present about 0.008 to about 8 parts per million of the copper. The blend may then be cast or otherwise formed and cured at a temperature in a range of about 50 C. to 150 C.

The copper naphthenate of the above examples may be replaced, in whole or in part, with any other resin-soluble copper salt of an organic acid such as, for example, saturated and unsaturated fatty acids having at least 4 carbon atoms (oleic, linoleic, stearic, palmitic, etc.); acids derived from natural resins (abietic, pimaric, etc.); acids of cylic saturated hydrocarbons, such as cyclo hexyl carbonic acid; acids of aromatic hydrocarbons, such as benzoic acid; and the like. The resin-soluble copper salt may he formed in situ by adding metallic copper to the resin, whereupon the copper reacts with the acidic constituents of the resin itself to produce the salt. Copper salts of strong acids, such as sulfonic acids, keto-acids and acids having halogen atoms near the carboxyl group are not always desirable, at least in the production of articles required to possess optimum optical properties, since such acids may react with certain resin components and affect the optical properties of the finished article.

In addition to the advantages specifically pointed out above, the use of a resin-soluble copper salt permits the casting of sheets which have excellent optical properties, the sheet surfaces being entirely free from blemishes and the sheet interiors being free from refractive enclosures of the type which are usually found in sheets cast from conventional compositions. The lowering of the peak of exotherm, brought about by addition of the copper compound, eliminates many of the difiiculties encountered in the casting of sheets over /2.-inch in thickness, due to even and uniform heating, and adequate dissipation of the heat of reaction. For essentially the same reason, through use of the copper salt, temperature control of the resin and mold during the casting and catalyzing operations becomes less important. Moreover, and again for the same reason, the eflFect of variations in the reactivity of various production batches of resin is minimized by the addition of copper.

Having fully described my invention, it is to be understood that I do not wish to be limited to the details set forth, :but my invention is of the full scope of the appended claims.

I claim:

1. A new. composition of matter comprising (A) a polyester of a dihydric alcohol and an ethylenically unsat urated dicarboxylic acid, (B) a compound having a polymerizable CH C group, (C) a gelation inhibitor comprising a quaternary ammonium salt of a non-oxidizing acid at least as strong as acetic acid, (D) a peroxide polymerization catalyst and (E) a minor effective proportion of a copper salt of an organic acid sufficient to provide at least about 0.008 part per million of copper, based upon the weight of (A) and (B), in solution in (A) and (B).

2. A new composition of matter comprising (A) a polyester of a dihydric alcohol and an ethylenically unsaturated dicarboxylic acid, (B) from about to about 60 percent by weight, based on the weight of the copolymerizable mixture, of a compound having a polymerizable CH =C group, (C) from about 0.01 to about 2.0 percent :by weight, based upon the weight of (A) and (B), of a gelation inhibitor comprising a quaternary ammonium salt of a non-oxidizing acid at least as strong as acetic acid,

(D) from about 0.1 to about 5 percent by weight, based on the weight of the copolymerizable mixture, of a peroxide polymerization catalyst and (E) a minor effective proportion of a copper salt of a monocarboxylic acid having at least 4 carbon atoms, said proportion being sufiicient to provide from about 0.008 to about 8 parts per million of copper, based upon the Weight of (A) and (B), in solution in (A) and (B).

3. A new composition of matter comprising (A) a polyester of a dihydric alcohol and an ethylenically unsaturated dicarboxylic acid, (B) from about 10 to about 60 percent by weight, based on the weight of the copolymerizable mixture, of a compound having a polymerizable 'CH =C group, (C) from about 0.01 to about 2.0 percent by weight, based upon the weight of (A) and (B), of a gelation inhibitor comprising a quaternary ammonium salt of a non-oxidizing acid at least as strong as acetic acid, (D) from about 0.1 to about 5 percent by weight, based on the weight of the copolymerizable mixture, of a peroxide polymerization catalyst and (E) a minor effective proportion of copper naphthenate sufficient to provide from about 0.008 to about 8 parts per million of copper, based upon the weight of (A) and (B), in solution in (A) and (B).

4. A new composition of matter comprising (A) a polyester of a dihydric alcohol and an ethylenically unsaturated dicarboxylic acid, (B) from about 10 to about 60 percent by weight, based on the weight of the copolymerizable mixture, of styrene, (C) from about 0.01 to about 2.0 percent by weight, based upon the weight of (A) and (B), of a gelation inhibitor comprising a quaternary ammonium salt of a non-oxidizing acid at least as strong as acetic acid, (D) from about 0.1 to about 5 percent by weight, based on the weight of the copolymerizable mixture, of a peroxide polymerization catalyst and (E) a minor effective proportion of copper naphthenate sufficient to provide from about 0.008 to about 8 parts per million of copper, based upon the weight of (A) and (B), in solution in (A) and (B).

5. A method of increasing the storage life of a copolymerizable mixture consisting essentially of a liquid unsaturated polyester resin, said resin being obtained by the esterification of a compound selected from the group consisting of an alpha, beta-ethylenic dicarboxylic acid and the anhydride thereof with a polyhydric alcohol, and a reactive monomeric substance having a group, the improvement of which consists in adding thereto about 0.01 to 2% by weight of a chemical stabilizer selected from the group consisting of phenols, quinones, mono-amine salts, and quaternary ammonium salts of non oxidizing acids at least as strong as acetic acid and about 0.008 to about 8 parts of copper per million parts of copolymerizable mixture, said copper being in the form of a copper salt which is soluble in the liquid polyester, and subsequently storing said mixture as such at ordinary temperatures.

6. A method as in claim 5, wherein the copper salt is copper naphthenate.

7. A method of increasing the storage life of a copolymerizable mixture consisting essentially of a liquid unsaturated polyester resin, said resin being obtained by the esterification of maleic acid anhydride with propylene glycol, and a reactive monomeric substance having a group, the improvement of which consists in adding thereto about 0.01 to 2% by weight of a chemical stabilizer selected from the group consisting of phenols, quinones, mono-amine salts, and quaternary ammonium salts of non-oxidizing acids at least as strong as acetic acid and about 0.008 to about 8 parts of copper per million parts of copolymerizable mixture, said copper being in the form of a copper salt which is soluble in the liquid polyester,

References Cited UNITED STATES PATENTS Foster et a1. 260-861 Singleton et a1. 260-863 Parker 260-873 Meyer et al 260-865 10 Parker 260865 Hoppens 260872 Parker 260-866 1 4 FOREIGN PATENTS 9/ 1949 Great Britain.

OTHER REFERENCES Organic Chemistry, Fieser and Fieser, 2nd ed. Pub.

by Reinhold Pub. Corp. (1950), pp. 555-561.

Organic Chemistry, Karrer (1938), 1st ed. Published by Nordeman Publishing Co. Inc., pp. 339-347.

GEORGE F. LESMES, Primary Examiner.

U.S. Cl. X.R.

gg gg UNITED STATES PATENT OFFICE CERTIFICATE OF CORRECTION Patent No. 3, 437,715 Dated April 8 1969 Inventor(s) Ettore DaFano It is certified that error appears in the above-identified patent and that said Letters Patent are hereby corrected as shown below:

[ Column 13, the following U.S. patent was omitted from the list of References Cited and should be added:

-- 2,822,344 2/1958 Duhnkrack SIGNED MU SEALED sea-m (SEAL) Attest:

Edward M Flctchfl', II.

A o WILLIAM E- 'S-OHUYLER, JR. testing on Commissioner of Patents 

